Information processing system

ABSTRACT

In a control device of the present invention, a whole upper limit power value, which is the upper limit power value of a whole system including a plurality of information processing devices, and an individual power value range including a predetermined range of values which can be set on each of the information processing devices are stored. The control device includes a setting part configured to set the upper limit power value of each of the information processing devices to a value within the individual power value range so that the total of the upper limit power values of the information processing devices does not exceed the whole upper limit power value.

INCORPORATION BY REFERENCE

This application is based upon and claims the benefit of priority fromJapanese patent application No. 2016-021981, filed on Feb. 8, 2016, thedisclosure of which is incorporated herein in its entirety by reference.

TECHNICAL FIELD

The present invention relates to an information processing system. Morespecifically, the present invention relates to an information processingsystem which shares a power supply among a plurality of informationprocessing devices.

BACKGROUND ART

In facilities such as data centers, efficient placement and operation ofserver computers is required. For example, as an information processingsystem, a rack server is configured by mounting a plurality of servercomputers and a power supply device on a rack, so that the integrationdensity of the physical servers is increased.

In this case, the plurality of server computers share the power supplydevice, and they share it within an upper limit power value set on thepower supply device in total. However, the servers may be brought into ahigh-load state during operation, and there is a fear that the totalpower exceeds the upper limit power value set on the power supplydevice. In order to respond to such a situation, in Patent Document 1,power control on each of the servers is executed so that the total powerdoes not exceed the upper limit power value set on the power supplydevice.

-   Patent Document 1: Japanese Unexamined Patent Application    Publication No. JP-A 2012-226496

However, in a case where power control on each of the server computersis executed in consideration of the upper limit power value of the wholesystem as described above, there is a fear that the arithmeticprocessing performance of the server computers considerablydeteriorates. This is because the arithmetic processing performance ofthe server computers are not necessarily proportional to powerconsumption. Then, the abovementioned technique causes a problem that,though system down due to power excess of the whole system can beavoided, the arithmetic processing performance of some of the servercomputers deteriorates and performance of the whole system deteriorates.

SUMMARY OF THE INVENTION

Accordingly, an object of the present invention is to solve the problemthat arithmetic processing performance deteriorates while the upperlimit power of the whole information processing system is maintained.

In a control device as an aspect of the present invention, a whole upperlimit power value and an individual power value range are stored. Thewhole upper limit power value is an upper limit power value of a wholesystem including a plurality of information processing devices. Theindividual power value range includes a predetermined range of valueswhich can be set on each of the information processing devices.

The control device includes a setting part configured to set an upperlimit power value of each of the information processing devices to avalue within the individual power value range so that a total of upperlimit power values of the information processing devices does not exceedthe whole upper limit power value.

Further, a control device as another aspect of the present inventionincludes a setting part configured to set an upper limit power value ofeach of a plurality of information processing devices to a value withinan individual power value range including a predetermined range ofvalues which can be set on each of the information processing devices sothat a total of upper limit power values of the information processingdevices does not exceed a whole upper limit power value, the whole upperlimit power value being an upper limit power value of a whole systemincluding the information processing devices.

Further, a computer-readable medium storing a program as another aspectof the present invention is a computer-readable medium storing a programincluding instructions for causing a control device to realize a settingpart configured to set an upper limit power value of each of a pluralityof information processing devices to a value within an individual powervalue range including a predetermined range of values which can be seton each of the information processing devices so that a total of upperlimit power values of the information processing devices does not exceeda whole upper limit power value, the whole upper limit power value beingan upper limit power value of a whole system including the informationprocessing devices.

Further, a control method as another aspect of the present inventionincludes setting an upper limit power value of each of a plurality ofinformation processing devices to a value within an individual powervalue range including a predetermined range of values which can be seton each of the information processing devices so that a total of upperlimit power values of the information processing devices does not exceeda whole upper limit power value, the whole upper limit power value beingan upper limit power value of a whole system including the informationprocessing devices.

With the configurations as described above, the present invention canrestrict deterioration of arithmetic processing performance, whilemaintaining the upper limit power of the entire information processingsystem.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram showing the configuration of an informationprocessing system in a first exemplary embodiment of the presentinvention;

FIG. 2 is a diagram showing the relation between upper limit power of anode disclosed in FIG. 1 and arithmetic processing performance;

FIG. 3 is a diagram showing the way the upper limit power value for eachnode disclosed in FIG. 1 is set;

FIG. 4 is a diagram showing the way the upper limit power value for eachnode disclosed in FIG. 1 is set;

FIG. 5 is a diagram showing the way the upper limit power value is setfor each node disclosed in FIG. 1;

FIG. 6 is a diagram showing the way the upper limit power value for eachnode disclosed in FIG. 1 is set;

FIG. 7 is a flowchart showing an operation of a control device disclosedin FIG. 1;

FIG. 8 is a flowchart showing the operation of the control devicedisclosed in FIG. 1;

FIG. 9 is a block diagram showing a configuration of the control devicein a second exemplary embodiment of the present invention;

FIG. 10 is a block diagram showing another configuration of the controldevice in the second exemplary embodiment of the present invention;

FIG. 11 is a flowchart showing an operation of the control device in thesecond exemplary embodiment of the present invention:

FIG. 12 is a block diagram showing another configuration of the controldevice in a third exemplary embodiment of the present invention; and

FIG. 13 is a flowchart showing an operation of the control device in thethird exemplary embodiment of the present invention.

EXEMPLARY EMBODIMENT First Exemplary Embodiment

A first exemplary embodiment of the present invention will be describedwith reference to FIGS. 1 to 8. FIG. 1 is a diagram for describing theconfiguration of an information processing system in the first exemplaryembodiment. FIG. 2 is a diagram showing the relation between upper limitpower of a node and arithmetic processing performance. FIGS. 3 to 6 arediagrams showing the way the upper limit power value for each node isset. FIGS. 7 and 8 are flowcharts showing the operation of the controldevice.

As shown in FIG. 1, the information processing system in this exemplaryembodiment includes a plurality of nodes A to D, which are informationprocessing devices each including an arithmetic device and a storagedevice, a power supply device 1 supplying power to the nodes A to D, anda control device 10 controlling supply of power to the nodes A to D bythe power supply device 1.

For example, the information processing system is configured in the formof a rack server. In other words, the information processing system isformed by placing each device configuring the information processingsystem on each shelf of a rack having a plurality of shelves. As oneexample, the information processing system is configured by mounting aserver group composed of the plurality of nodes A to D, the power supplydevice 1, and a rack manager including the control device 10 on eachunit which is each shelf of the server rack. However, the informationprocessing system is not limited to the configuration in the form of arack server.

The nodes A to D operate when supplied with power by the power supplydevice 1. The nodes A to D then share the power supply device 1 amongthem. Therefore, the nodes A to D share the power supply device 1 withinthe range of a whole upper limit power value, which is set in the powersupply device 1 and represents the upper limit value of supplied power.In other words, a whole upper limit power value is the upper limit valueof power supplied by the power supply device 1 to the whole systemconfigured by the plurality of nodes A to D, and is predetermined inaccordance with the performance of the power supply device 1.

For each of the nodes A to D, a node upper limit power value is set,which is the upper limit value of power supplied thereto. Because a nodeupper limit power value is set for each of the nodes A to D, the valuesfor the respective nodes A to D may be different. The respective nodes Ato D are supplied with power by the power supply device 1 within thenode upper limit power value set thereon.

Power consumption of each of the nodes A to D varies depending on itsoperation state. For example, when load is low, the value of the powerconsumption is lower than the node upper limit power value, whereas whenload is high, the value of the power consumption is high and may be morethan the node upper limit power value. In other words, in a case whereany of the nodes A to D needs more power than its node upper limit powervalue when load is high, the node may be supplied with more power thanits node upper limit value. Accordingly, the power supply device 1 maysupply the nodes A to D with power which is more than the whole upperlimit power value.

Further, each of the nodes A to D includes a BMC (Base ManagementController) 21 monitoring installed hardware, and a sensor 22 (adetection part) which detects power consumption. The sensor 22 detectspower consumed in detection by the node with the sensor 22 installed, aspower consumption. The sensor 22 detects power consumed by the node inresponse to an instruction by a detection part 11 of the control device10, which will be described later, and notifies it to detection part 11.

The control device 10 is formed of an information processing deviceincluding an arithmetic device and a storage device. The control device10 includes the detection part 11 and a setting part 12 which arestructured by installing a program into the arithmetic device includedthereby. Moreover, the control device 10 includes a storage part 13formed in the storage device included thereby and a register 14 whichtemporarily stores information. Meanwhile, the storage part 13 may beprovided outside the control device 10.

In the storage part 13, a “whole upper limit power value” is stored,which is set in the power supply device 1 and represents the upper limitvalue of power supplied to all the nodes A to D. The whole upper limitpower value is determined in accordance with the performance of thepower supply device 1 and stored by the operator into the storage part13 in advance. However, the whole upper limit power value may not bestored in the control device 10 and may be acquired from outside by thecontrol device 10.

Further, in the storage part 13, an “individual power value range” isstored, which represents the upper limit value of power that can be setindividually on each of the nodes A to D, and which is composed ofvalues in a given range. The individual power value range represents therange of values set in accordance with the characteristic of each of thenodes A to D, specifically, power values determined to exhibit higharithmetic processing efficiency with respect to power consumption. Anindividual power value range set in this exemplary embodiment will bedescribed with reference to FIG. 2.

FIG. 2 is a graph G showing the relation between power consumption (W)and arithmetic processing performance (GFLOPS) of a node. As shown inthis graph G, arithmetic processing performance of the node is notnecessarily proportion to power consumption. Therefore, a range of powerconsumption values determined by a preset criterion to show higharithmetic processing performance with respect to power consumption isset as an individual power value range. In other words, a range of powerconsumption values where higher arithmetic performance can be obtainedwith lower power consumption is set as an individual power value range.In the example shown in FIG. 2, as shown with an arrow, the range of“250 W to 350 W” is set as an individual power value range. A value inthis range is mainly set as a node upper limit value, which is the upperlimit value of power consumption of each of the nodes A to D asdescribed later.

In this exemplary embodiment, the nodes A to D all have the sameconfigurations and the same performances, so that the individual powervalue ranges of the nodes A to D are the same ranges. However, theindividual power value ranges of the nodes A to D may be different fromeach other. For example, in a case where the nodes A to D have differentconfigurations, performances, uses, and so on, different individualpower value ranges may be used depending on the characteristics of therespective nodes A to D.

The detection part 11 detects power consumptions of the nodes A to D. Tobe specific, the detection part 11 issues an instruction to detect powerconsumption to the sensor 22 of each of the nodes A to D, and detectspower consumptions returned by the sensors 22 of the respective nodes Ato D in response to the instruction, as power consumptions of the nodesA to D. Then, the detection part 11 notifies the setting part 12 of thedetected power consumptions of the respective nodes A to D, or storesthe total value of the power consumptions of the respective nodes A to Das a whole power consumption value into the register 14.

The detection part 11 detects power consumptions of the respective nodesA to D in sequence. Specifically, as described later, in executing aprocess of setting the node upper limit value for each of the nodes A toD, for example, the detection part 11 detects the power consumptions ofthe nodes A to D one by one every given time interval or every time thelast setting process ends. Meanwhile, the detection part 11 may detectthe power consumptions of the respective nodes A to D at one time.

The setting part 12 sets a node upper limit power value, which is theupper limit value of power for each node, on each of the nodes A to D.For example, the setting part 12 sets equal upper limit power values onall the nodes A to D, or individually sets a node upper limit powervalue for each of the nodes A to D. Below, an specific example of theprocess of setting node upper limit power values on the nodes A to Dwill be described with reference to FIGS. 3 to 8.

Now, the process of setting equal upper limit power values on all thenodes A to D will be described with reference to FIGS. 3 and 4 and aflowchart of FIG. 7. First, in an information processing systemincluding four nodes A to D as shown in FIG. 3, a whole upper limitpower value, which is the upper limit value of total power, is set andstored into the storage part 13 (step S1 of FIG. 7). In this example,the whole upper limit power value is set to 1200 W.

Further, in this example, as described on the first line above each ofthe nodes A to D in FIG. 3, a node upper limit power value (W) is set oneach of the nodes A to D. Meanwhile, on the second line above each ofthe nodes A to D in FIG. 3, arithmetic processing performance (GFLOPS)in the case of operating at the set node upper limit power value (W) isdescribed. For example, 400 W is set as the upper limit power value inthe nodes A and B, and 200 W is set as the upper limit power value inthe nodes C and D. In this case, as described in the lower right portionof FIG. 3, the total of the upper limit power values of all the nodes Ato D is 1200 W, and arithmetic processing performance at this moment is960 GFLOPS.

After that, power consumptions of the respective nodes A to D aredetected by the detection part 11, and a whole power consumption value,which is the total of the power consumptions of the respective nodes Ato D, is stored into the register 14 (step S2 of FIG. 7). Then, thesetting part 12 compares the whole power consumption value stored in theregister 14 with the whole upper limit power value stored in the storagepart 13 (step S3 of FIG. 7). As a result of the comparison, in a casewhere the whole power consumption value is more than the whole upperlimit power value (step S3 of FIG. 7: Yes), the setting part 12 setsequal node upper limit power values on all the nodes A to D (step S4 ofFIG. 7).

To be specific, the setting part 12 sets upper limit power values set onthe respective nodes A to D to values within the individual power valuerange stored in the storage part 13, and also keeps the total of theupper limit power values set on all the nodes A to D from exceeding thewhole upper limit power value. In this example, the individual powervalue range is “250 W to 350 W” and the whole upper limit power value is“1200 W,” so that the setting part 12 sets an upper limit power valueset to be equal on all the nodes A to D, to “300 W.” Consequently, thenodes A to D operate with power less which the set node upper limitpower value.

Now, a state where an upper limit power value “300 W” is set on all thenodes A to D is shown in FIG. 4. As described in FIG. 4, arithmeticprocessing performances of the nodes A to D are 350 GFLOPS,respectively. Then, as described in the lower right portion of FIG. 4,the total of the upper limit power values of all the nodes A to D is“1200 W” and is not more than the whole upper limit power value, and thetotal of the arithmetic processing performances at this moment is “1400GFLOPS” and is a large value before the setting of the power value ischanged. Thus, to whole power consumption of all the nodes A to D doesnot increase and it is possible to increase the arithmetic performance.

In the above description, the node upper limit power values of the nodesA to D are set to equal values, but the upper limit power values may notbe set equal on the nodes A to D. For example, within the individualpower value range, different node upper limit power values may be setfor each of the nodes A to D. Moreover, in the above description, nodeupper limit power values are set on the respective nodes A to D in acase where the whole power consumption value is more than the wholeupper limit power value, but the node upper limit value for each of thenodes A to B may be set at any timing.

After thus setting the node upper limit power values, the setting part12 checks the total of power consumptions of the respective nodes A to Dand the total of the node upper limit power values via the detectionpart 11 (step S5 of FIG. 7). Then, after that, the setting part 12executes a process of individually setting a node upper limit powervalue for each of the nodes A to D. The way this process is executedwill be described with reference to flowcharts of FIGS. 5, 6 and 8. Theprocess described below is not limited to a case of executing aftersetting the node upper limit power values of the respective nodes A to Dto equal values as described above, and may be executed any timing.

In the following process, in accordance with the magnitude relationbetween power consumption of each of the nodes A to D and a node upperlimit power value, the node upper limit power value is set by changingmainly within an individual power value range. For example, in a casewhere the power consumption value of the node is more than the nodeupper limit power value, the node is short of power, so that the nodeupper limit value is raised and set. On the other hand, in a case wherethe power consumption value of the node is less than the node upperlimit power value, the node has surplus power, so that the node upperlimit value is reduced and set. Moreover, in a case where the powerconsumption of the node is less than the individual power value range,the node upper limit value is reduced and set to a value smaller thanthe individual power value range (herein, 200 W is the lower limitvalue).

Furthermore, in the following process, a node upper limit power value tobe set is set in accordance with the following “power levels:”

Power level 1: limit to 350 W or less;

Power level 2: limit to 340 W or less;

Power level 3: limit to 330 W or less;

Power level 4: limit to 320 W or less;

Power level 5: limit to 310 W or less;

Power level 6: limit to 300 W or less;

Power level 7: limit to 290 W or less;

Power level 8: limit to 280 W or less;

Power level 9: limit to 270 W or less;

Power level 10: limit to 260 W or less;

Power level 11: limit to 250 W or less;

Power level 12: limit to 240 W or less;

Power level 13: limit to 230 W or less;

Power level 14: limit to 220 W or less;

Power level 15: limit to 210 W or less; and

Power level 16: limit to 200 W or less.

As shown in parenthesis on the second line within each node in FIG. 5(1), the node upper limit power values of all the nodes A to D are setto the power level 6 (300 W). Moreover, as shown on the right side onthe first line within each node in FIG. 5 (1), power consumptions of therespective nodes A to D are 300 W, 300 W, 200 W and 200 W. Under thiscondition, the detection part 11 detects power consumption in order ofthe node A, B, C and D, and every time detecting power consumption ofeach of the nodes A to D, the setting part 12 sets the node upper limitpower value of the detection target node.

First, in the condition of FIG. 5 (1), the “node A” is the target ofsetting. In a case where the total of the node upper limit power valuesis not more than the whole upper limit power value (step S6 of FIG. 8:Yes), the setting part 12 detects the power consumption of the node Avia the detection part 11 (step S7 of FIG. 8). Then, the setting part 12checks whether or not the power consumption of the node A is a valuewithin the individual power value range (250 to 350 W) stored in thestorage part 13 (step S8 of FIG. 8). In this condition, the powerconsumption of the node A (300 W) is within the individual power valuerange (step S8 of FIG. 8: Yes) and is not more than the node upper limitpower value of the node A (300 W) (step S12 of FIG. 8: No). Therefore,the setting part 12 does not change the power level, namely, the nodeupper limit power value of the node A and keeps it 300 W.

Subsequently, in the condition of FIG. 5 (2), the “node B” is the targetof setting. In a case where the total of the node upper limit powervalues is not more than the whole upper limit power value (step S6 ofFIG. 8: Yes), the setting part 12 detects the power consumption of thenode B via the detection part 11 (step S7 of FIG. 8). Then, the settingpart 12 checks whether or not the power consumption of the node B is avalue within the individual power value range (250 to 350 W) stored inthe storage part 13 (step S8 of FIG. 8). In this condition, the powerconsumption of the node B (300 W) is within the individual power valuerange (step S8 of FIG. 8: Yes) and is not more than the node upper limitpower value of the node B (300 W) (step S12 of FIG. 8: No). Therefore,the setting part 12 does not change the power level, namely, the nodeupper limit power value of the node B and keeps it 300 W.

Subsequently, in the condition of FIG. 5 (3), the “node C” is the targetof setting. In a case where the total of the node upper limit powervalues is not more than the whole upper limit power value (step S6 ofFIG. 8: Yes), the setting part 12 detects the power consumption of thenode C via the detection part 11 (step S7 of FIG. 8). Then, the settingpart 12 checks whether or not the power consumption of the node C is avalue within the individual power value range (250 to 350 W) stored inthe storage part 13 (step S8 of FIG. 8). In this condition, the powerconsumption of the node C (220 W) is not within the individual powervalue range (step S8 of FIG. 8: No) and is not more than the node upperlimit power value of the node C (220 W) (step S9 of FIG. 8: No). Becausethe node upper limit power value of the node C (300 W) is not the lowerlimit value (200 W) (step S10 of FIG. 8: No), the setting part 12 setsthe power level of the node C one level down to the power level 7,thereby setting the node upper limit power value decreased from 300 W to290 W (step S11 of FIG. 8) (see the underlined second line of the node Cin FIG. 5 (4)).

Subsequently, in the condition of FIG. 5 (4), the “node D” is the targetof setting. In a case where the total of the node upper limit powervalues is not more than the whole upper limit power value (step S6 ofFIG. 8: Yes), the setting part 12 detects the power consumption of thenode D via the detection part 11 (step S7 of FIG. 8). Then, the settingpart 12 checks whether or not the power consumption of the node D is avalue within the individual power value range (250 to 350 W) stored inthe storage part 13 (step S8 of FIG. 8). In this condition, the powerconsumption of the node D (230 W) is not within the individual powervalue range (step S8 of FIG. 8: No), and the power consumption of thenode D (230 W) is not more than the node upper limit power value (300 W)(step S9 of FIG. 8: No). Because the node upper limit power value of thenode D (300 W) is not the lower limit value (200 W) (step S10 of FIG. 8:No), the setting part 12 sets the power level of the node D one leveldown to the power level 7, thereby setting the node upper limit powervalue decreased from 300 W to 290 W (step S11 of FIG. 8) (see theunderlined second line of the node D in FIG. 5 (5)).

Subsequently, in the condition of FIG. 5 (5), the “node A” is the targetof setting. In a case where the total of the node upper limit powervalues is not more than the whole upper limit power value (step S6 ofFIG. 8: Yes), the setting part 12 detects the power consumption of thenode A via the detection part 11 (step S7 of FIG. 8). Then, the settingpart 12 checks whether or not the power consumption of the node A is avalue within the individual power value range (250 to 350 W) stored inthe storage part 13 (step S8 of FIG. 8). In this condition, the powerconsumption of the node A (310 W) is within the individual power valuerange (step S8 of FIG. 8: Yes), and the power consumption of the node A(310 W) is more than the node upper limit power value (300 W) (step S12of FIG. 8: Yes). The total of the node upper limit power values (1180 W)is not more than the whole upper limit power value (1200 W) (step S13 ofFIG. 8: No), and the node upper limit power value of the node A (300 W)is not the upper limit value of the individual power value range (350 W)(step S14 of FIG. 8: No). Therefore, the setting part 12 sets the powerlevel of the node A one level up to the power level 5, thereby settingthe node upper limit power value increased from 300 W to 310 W (stepsS15 of FIG. 8) (see the underlined second line of the node A of FIG. 6(6).

Subsequently, in the condition of FIG. 6 (6), the “node B” is the targetof setting. In this case, as in the case of the node A of FIG. 5 (5)described above, the setting part 12 sets the power level of the node Bone level up to the power level 5, thereby setting the node upper limitvalue increased from 300 W to 310 W (step S15 of FIG. 8).

After that, in the condition of FIG. 6(m) through some steps, the “nodeD” is the target of setting. Then, in a case where the total of the nodeupper limit power values is not more than the whole upper limit powervalue (step S6 of FIG. 8: Yes), the setting part 12 detects the powerconsumption of the node D via the detection part 11 (step S7 of FIG. 8).Then, the setting part 12 checks whether or not the power consumption ofthe node D is a value within the individual power value range (250 to350 W) stored in the storage part 13 (step S8 of FIG. 8). In thiscondition, the power consumption of the node D (220 W) is not within theindividual power value range (step S8 of FIG. 8: No), and the powerconsumption of the node D (220 W) is not more than the node upper limitpower value (240 W) (step S9 of FIG. 8: No). Because the node upperlimit power value of the node D (240 W) is not the lower limit value(200 W) (step S10 of FIG. 8: No), the setting part 12 sets the powerlevel of the node D one more level down, thereby setting the node upperlimit power value decreased from 240 W to 230 W (step S11 of FIG. 8).Thus, in a case where the power consumption of the node is lower thanthe lower limit value (250 W) of the individual power value range, thesetting part 12 sets the node upper limit power value down to a smallervalue than the lower limit value (250 W) of the individual power valuerange.

After that, in the condition of FIG. 6(n) through some more steps, the“node D” is the target of setting. Then, in a case where the total ofthe node upper limit power values is not more than the whole upper limitpower value (step S6 of FIG. 8: Yes), the setting part 12 detects thepower consumption of the node D via the detection part 11 (step S7 ofFIG. 8). Then, the setting part 12 checks whether or not the powerconsumption of the node D is a value within the individual power valuerange (250 to 350 W) stored in the storage part 13 (step S8 of FIG. 8).In this condition, the power consumption of the node D (240 W) is notwithin the individual power value range (step S8 of FIG. 8: No), and thepower consumption of the node D (240 W) is more than the node upperlimit power value (230 W) (step S9 of FIG. 8: Yes). The total of thenode upper limit power values (1190 W) is not more than the whole upperlimit power value (1200 W) (step S13 of FIG. 8: No), and the node upperlimit power value of the node D (230 W) is not the upper limit value(350 W) of the individual power value range (step S14 of FIG. 8: No).Therefore, the setting part 12 sets the power level of the node D onelevel up, thereby setting the node upper limit power value increasedfrom 230 W to 240 W (step S15 of FIG. 8).

Accordingly, the information processing system in the present inventionsets the node upper limit power values of the respective nodes A to D inaccordance with the operation conditions of the respective nodes, whilekeeping the upper limit power value of the whole system. Consequently,it is possible to increase arithmetic processing performance whilerestricting increase of power consumption and avoiding system down. As aresult, it is possible to realize system operation with efficiency andhigh reliability.

Second Exemplary Embodiment

Next, a second exemplary embodiment of the present invention will bedescribed with reference to FIGS. 9 to 11. FIGS. 9 to 11 are blockdiagrams showing the configuration of a control device in the presentinvention. FIG. 11 is a flowchart showing the operation of the controldevice.

As shown in FIG. 9, in a control device 100, a whole upper limit powervalue 101 and an individual power value range 102 are stored. The wholeupper limit power value 101 is the upper limit power value of the wholesystem including a plurality of information processing devices 200, andthe individual power value range 102 is composed of a predeterminedrange of values which can be set on each of the information processingdevices. Moreover, the control device 100 includes a setting part 110which sets the upper limit power value of each of the informationprocessing devices 200 to a value within the individual power valuerange 102 so that the total of the upper limit power values of theinformation processing devices 200 does not exceed the whole upper limitpower value 101. Herein, the setting part 110 is structured by executionof a program in an arithmetic device included by the control device 100.

Further, as shown in FIG. 10, the control device 100 of the presentinvention may include only the setting part 110 without storing thewhole upper limit power value 101 or the individual power value range102 described above.

According to the control device described above, first, the setting part110 acquires information of the whole upper limit power value and theindividual power value range from the device itself or from outside(step S101 of FIG. 11). Then, the setting part 110 sets the upper limitpower value of each of the information processing devices 200 to a valuewithin the individual power value range 102 (step S102 of FIG. 11). Thesetting part 110 then sets the upper limit power value of each of theinformation processing devices 200 so that the total of the upper limitpower values of the information processing devices 200 does not exceedthe whole upper limit power value 101.

Thus, according to the present invention, while the upper limit powervalue of the whole system is maintained, an upper limit power value isset for each of the information processing devices within a range whereefficient arithmetic performance can be exerted. Therefore, it ispossible to increase arithmetic processing performance while restrictingpower consumption, and it is thereby possible to realize highlyefficient and reliable system operation.

Third Exemplary Embodiment

Next, a third exemplary embodiment of the present invention will bedescribed with reference to FIGS. 12 and 13. FIG. 12 is a block diagramshowing the configuration of a control device in the present invention.FIG. 13 is a flowchart showing the operation of the control device.

First, as shown in FIG. 12, the control device 100 includes the settingpart 110 which is the same as in the second exemplary embodiment. Inaddition to this, the control device 100 includes a detection part 120which detects the power value of each of the information processingdevices 200. The setting part 110 is configured to, in accordance withthe result of comparison of the detected power value of the informationprocessing device 200 with the upper limit power value set on theinformation processing device 200, set the upper limit power value ofthe information processing device 200 to a value within the individualpower value range so that the total of the upper limit power values ofthe plurality of information processing devices 200 does not exceed thewhole upper limit power value. The setting part 110 and the detectionpart 120 are structured by execution of a program in an arithmeticdevice included by the control device 100.

According to the control device described above, first, the setting part110 acquires information of the whole upper limit power value and theindividual power value range from the device itself or from outside(step S111 of FIG. 13). Then, the detection part 120 detects the powervalue of each of the information processing devices 200 (step S112 ofFIG. 13). Then, the setting part 110 compares the detected power valueof the information processing device 200 with the upper limit powervalue set on the information processing device 200 (step S113 of FIG.13). After that, in accordance with the comparison result, the settingpart 110 sets the upper limit power value of the information processingdevice 200 to a value within the individual power value range so thatthe total of the upper limit power values of the plurality ofinformation processing devices 200 does not exceed the whole upper limitpower value (step S114 of FIG. 13).

Accordingly, in the present invention, while the upper limit power valueof the whole system is maintained, an upper limit power value is set foreach of the information processing devices within a range whereefficient arithmetic performance can be exerted in accordance with theoperation state of the information processing device. Therefore, it ispossible to increase arithmetic processing performance while restrictingpower consumption, and it is thereby possible to realize highlyefficient and reliable system operation.

<Supplementary Notes>

The whole or part of the exemplary embodiments disclosed above can bedescribed as the following supplementary notes. Below, a control device,a program, and the overall configuration of a control method accordingto the present invention will be described. However, the presentinvention is not limited to the following configurations.

(Supplementary Note 1)

A control device, wherein a whole upper limit power value and anindividual power value range are stored, the whole upper limit powervalue being an upper limit power value of a whole system including aplurality of information processing devices, the individual power valuerange including a predetermined range of values which can be set on eachof the information processing devices,

the control device comprising a setting part configured to set an upperlimit power value of each of the information processing devices to avalue within the individual power value range so that a total of upperlimit power values of the information processing devices does not exceedthe whole upper limit power value.

(Supplementary Note 2)

The control device according to Supplementary Note 1, comprising adetection part configured to detect a power value of each of theinformation processing devices, wherein the setting part is configuredto set, in a case where a total of detected power values of theinformation processing devices is more than the whole upper limit powervalue, an upper limit power value of each of the information processingdevices to a value within the individual power value range so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.

(Supplementary Note 3)

The control device according to Supplementary Note 1 or 2, wherein thesetting part is configured to set upper limit power values of theinformation processing devices to uniform values within respectiveindividual power value ranges so that a total of the upper limit powervalues of the information processing devices does not exceed the wholeupper limit power value.

(Supplementary Note 4)

The control device according to any of Supplementary Notes 1 to 3,comprising a detection part configured to detect a power value of eachof the information processing devices, wherein the setting part isconfigured to set, in accordance with a result of comparison of thedetected power value of the information processing device with an upperlimit power value set on the information processing device, the upperlimit power value of the information processing device to a value withinthe individual power value range so that a total of upper limit powervalues of the respective information processing devices does not exceedthe whole upper limit power value.

(Supplementary Note 5)

The control device according to Supplementary Note 4, wherein thesetting part is configured to set, in a case where the detected powervalue of the information processing device is more than an upper limitpower value set on the information processing device, the upper limitpower value of the information processing device to a larger value thanthe current upper limit power value within the individual power valuerange so that a total of upper limit power values of the informationprocessing devices does not exceed the whole upper limit power value.

(Supplementary Note 6)

The control device according to Supplementary Note 4 or 5, wherein thesetting part is configured to set, in a case where the detected powervalue of the information processing device is less than an upper limitpower value set on the information processing device, the upper limitpower value of the information processing device to a smaller value thanthe current upper limit power value within the individual power valuerange so that a total of upper limit power values of the informationprocessing devices does not exceed the whole upper limit power value.

(Supplementary Note 7)

The control device according to any of Supplementary Notes 4 to 6,wherein the setting part is configured to set, in a case where thedetected power value of the information processing device is less thanan upper limit power value set on the information processing device andis not within the individual power value range, the upper limit powervalue of the information processing device to a smaller value than alower limit value of the individual power value range so that a total ofupper limit power values of the information processing devices does notexceed the whole upper limit power value.

(Supplementary Note 8)

The control device according to any of Supplementary Notes 4 to 7,wherein:

the detection part is configured to detect power values of therespective information processing devices in sequence; and

the setting part is configured to set, every time a power value of theinformation processing device is detected by the detection part, anupper limit power value of the information processing device so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.

(Supplementary Note 9)

A control device comprising a setting part configured to set an upperlimit power value of each of a plurality of information processingdevices to a value within an individual power value range including apredetermined range of values which can be set on each of theinformation processing devices so that a total of upper limit powervalues of the information processing devices does not exceed a wholeupper limit power value, the whole upper limit power value being anupper limit power value of a whole system including the informationprocessing devices.

(Supplementary Note 10)

The control device according to Supplementary Note 9, comprising adetection part configured to detect a power value of each of theinformation processing devices, wherein the setting part is configuredto set, in a case where a total of detected power values of theinformation processing devices is more than the whole upper limit powervalue, an upper limit power value of each of the information processingdevices to a value within the individual power value range so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.

(Supplementary Note 11)

The control device according to Supplementary Note 9 or 10, wherein thesetting part is configured to set upper limit power values of theinformation processing devices to uniform values within respectiveindividual power value ranges so that a total of the upper limit powervalues of the information processing devices does not exceed the wholeupper limit power value.

(Supplementary Note 12)

The control device according to any of Supplementary Notes 9 to 11,comprising a detection part configured to detect a power value of eachof the information processing devices,

wherein the setting part is configured to set, in accordance with aresult of comparison of the detected power value of the informationprocessing device with an upper limit power value set on the informationprocessing device, the upper limit power value of the informationprocessing device to a value within the individual power value range sothat a total of upper limit power values of the respective informationprocessing devices does not exceed the whole upper limit power value.

(Supplementary Note 12.1)

The control device according to Supplementary Note 12, wherein thesetting part is configured to set, in a case where the detected powervalue of the information processing device is more than an upper limitpower value set on the information processing device, the upper limitpower value of the information processing device to a larger value thanthe current upper limit power value within the individual power valuerange so that a total of upper limit power values of the informationprocessing devices does not exceed the whole upper limit power value.

(Supplementary Note 12.2)

The control device according to Supplementary Note 12 or 12.1, whereinthe setting part is configured to set, in a case where the detectedpower value of the information processing device is less than an upperlimit power value set on the information processing device, the upperlimit power value of the information processing device to a smallervalue than the current upper limit power value within the individualpower value range so that a total of upper limit power values of theinformation processing devices does not exceed the whole upper limitpower value.

(Supplementary Note 12.3)

The control device according to any of Supplementary Notes 12 to 12.2,wherein the setting part is configured to set, in a case where thedetected power value of the information processing device is less thanan upper limit power value set on the information processing device andis not within the individual power value range, the upper limit powervalue of the information processing device to a smaller value than alower limit value of the individual power value range so that a total ofupper limit power values of the information processing devices does notexceed the whole upper limit power value.

(Supplementary Note 12.4)

The control device according to any of Supplementary Notes 12 to 12.3,wherein:

the detection part is configured to detect power values of therespective information processing devices in sequence; and

the setting part is configured to set, every time a power value of theinformation processing device is detected by the detection part, anupper limit power value of the information processing device so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.

(Supplementary Note 13)

A control method comprising setting an upper limit power value of eachof a plurality of information processing devices to a value within anindividual power value range including a predetermined range of valueswhich can be set on each of the information processing devices so that atotal of upper limit power values of the information processing devicesdoes not exceed a whole upper limit power value, the whole upper limitpower value being an upper limit power value of a whole system includingthe information processing devices.

(Supplementary Note 14)

The control method according to Supplementary Note 13, comprising:

detecting a power value of each of the information processing devices;and

setting, in a case where a total of detected power values of theinformation processing devices is more than the whole upper limit powervalue, an upper limit power value of each of the information processingdevices to a value within the individual power value range so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.

(Supplementary Note 15)

The control method according to Supplementary Note 13 or 14, comprisingsetting upper limit power values of the information processing devicesto uniform values within respective individual power value ranges sothat a total of the upper limit power values of the informationprocessing devices does not exceed the whole upper limit power value.

(Supplementary Note 16)

The control method according to any of Supplementary Notes 13 to 15,comprising:

detecting a power value of each of the information processing devices;and

setting, in accordance with a result of comparison of the detected powervalue of the information processing device with an upper limit powervalue set on the information processing device, the upper limit powervalue of the information processing device to a value within theindividual power value range so that a total of upper limit power valuesof the respective information processing devices does not exceed thewhole upper limit power value.

(Supplementary Note 17)

The control method according to Supplementary Note 16, comprisingsetting, in a case where the detected power value of the informationprocessing device is more than an upper limit power value set on theinformation processing device, the upper limit power value of theinformation processing device to a larger value than the current upperlimit power value within the individual power value range so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.

(Supplementary Note 18)

The control method according to Supplementary Note 16 or 17, comprisingsetting, in a case where the detected power value of the informationprocessing device is less than an upper limit power value set on theinformation processing device, the upper limit power value of theinformation processing device to a smaller value than the current upperlimit power value within the individual power value range so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.

(Supplementary Note 19)

The control method according to any of Supplementary Notes 16 to 18,comprising setting, in a case where the detected power value of theinformation processing device is less than an upper limit power valueset on the information processing device and is not within theindividual power value range, the upper limit power value of theinformation processing device to a smaller value than a lower limitvalue of the individual power value range so that a total of upper limitpower values of the information processing devices does not exceed thewhole upper limit power value.

(Supplementary Note 20)

The control method according to any of Supplementary Notes 16 to 19,comprising:

detecting power values of the respective information processing devicesin sequence; and

setting, every time a power value of the information processing deviceis detected, an upper limit power value of the information processingdevice so that a total of upper limit power values of the informationprocessing devices does not exceed the whole upper limit power value.

(Supplementary Note 21)

A computer-readable medium storing a program comprising instructions forcausing a control device to realize a setting part configured to set anupper limit power value of each of a plurality of information processingdevices to a value within an individual power value range including apredetermined range of values which can be set on each of theinformation processing devices so that a total of upper limit powervalues of the information processing devices does not exceed a wholeupper limit power value, the whole upper limit power value being anupper limit power value of a whole system including the informationprocessing devices.

(Supplementary Note 22)

The computer-readable medium storing the program according toSupplementary Note 21, comprising instructions for further causing thecontrol device to realize a detection part configured to detect a powervalue of each of the information processing devices,

wherein the setting part is configured to set, in a case where a totalof detected power values of the information processing devices is morethan the whole upper limit power value, an upper limit power value ofeach of the information processing devices to a value within theindividual power value range so that a total of upper limit power valuesof the information processing devices does not exceed the whole upperlimit power value.

(Supplementary Note 23)

The computer-readable medium storing the program according toSupplementary Note 21 or 22, wherein the setting part is configured toset upper limit power values of the information processing devices touniform values within respective individual power value ranges so that atotal of the upper limit power values of the information processingdevices does not exceed the whole upper limit power value.

(Supplementary Note 24)

The computer-readable medium storing the program according to any ofSupplementary Notes 21 to 23, comprising instructions for furthercausing the control device to realize a detection part configured todetect a power value of each of the information processing devices,wherein the setting part is configured to set, in accordance with aresult of comparison of the detected power value of the informationprocessing device with an upper limit power value set on the informationprocessing device, the upper limit power value of the informationprocessing device to a value within the individual power value range sothat a total of upper limit power values of the respective informationprocessing devices does not exceed the whole upper limit power value.

(Supplementary Note 25)

The computer-readable medium storing the program according toSupplementary Note 24, wherein the setting part is configured to set, ina case where the detected power value of the information processingdevice is more than an upper limit power value set on the informationprocessing device, the upper limit power value of the informationprocessing device to a larger value than the current upper limit powervalue within the individual power value range so that a total of upperlimit power values of the information processing devices does not exceedthe whole upper limit power value.

(Supplementary Note 26)

The computer-readable medium storing the program according toSupplementary Notes 24 or 25, wherein the setting part is configured toset, in a case where the detected power value of the informationprocessing device is less than an upper limit power value set on theinformation processing device, the upper limit power value of theinformation processing device to a smaller value than the current upperlimit power value within the individual power value range so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.

(Supplementary Note 27)

The computer-readable medium storing the program according to any ofSupplementary Notes 24 to 26, wherein the setting part is configured toset, in a case where the detected power value of the informationprocessing device is less than an upper limit power value set on theinformation processing device and is not within the individual powervalue range, the upper limit power value of the information processingdevice to a smaller value than a lower limit value of the individualpower value range so that a total of upper limit power values of theinformation processing devices does not exceed the whole upper limitpower value.

(Supplementary Note 28)

The computer-readable medium storing the program according to any ofSupplementary Notes 24 to 27, wherein:

the detection part is configured to detect power values of therespective information processing devices in sequence; and

the setting part is configured to set, every time a power value of theinformation processing device is detected by the detection part, anupper limit power value of the information processing device so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.

The abovementioned program is stored in a storage device or recorded ona computer-readable recording medium. For example, the recording mediumis a portable medium such as a flexible disk, an optical disk, amagneto-optical disk and a semiconductor memory.

Although the present invention is described above with reference to theexemplary embodiments and so on, the present invention is not limited tothe exemplary embodiments described above. The configurations anddetails of the present invention can be changed in various manners thatcan be understood by one skilled in the art within the scope of thepresent invention.

DESCRIPTION OF REFERENCE NUMERALS

-   1 power supply device-   10 control device-   11 detection part-   12 setting part-   13 storage part-   14 register-   21 BMC-   22 sensor-   A to D node-   100 control device-   101 whole upper limit power value-   102 individual power range-   110 setting part-   120 detection part-   200 information processing device

1. A control device, wherein a whole upper limit power value and anindividual power value range are stored, the whole upper limit powervalue being an upper limit power value of a whole system including aplurality of information processing devices, the individual power valuerange including a predetermined range of values which can be set on eachof the information processing devices, the control device comprising asetting part configured to set an upper limit power value of each of theinformation processing devices to a value within the individual powervalue range so that a total of upper limit power values of theinformation processing devices does not exceed the whole upper limitpower value.
 2. The control device according to claim 1, comprising adetection part configured to detect a power value of each of theinformation processing devices, wherein the setting part is configuredto set, in a case where a total of detected power values of theinformation processing devices is more than the whole upper limit powervalue, an upper limit power value of each of the information processingdevices to a value within the individual power value range so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.
 3. The control deviceaccording to claim 1, wherein the setting part is configured to setupper limit power values of the information processing devices touniform values within respective individual power value ranges so that atotal of the upper limit power values of the information processingdevices does not exceed the whole upper limit power value.
 4. Thecontrol device according to claim 1, comprising a detection partconfigured to detect a power value of each of the information processingdevices, wherein the setting part is configured to set, in accordancewith a result of comparison of the detected power value of theinformation processing device with an upper limit power value set on theinformation processing device, the upper limit power value of theinformation processing device to a value within the individual powervalue range so that a total of upper limit power values of therespective information processing devices does not exceed the wholeupper limit power value.
 5. The control device according to claim 4,wherein the setting part is configured to set, in a case where thedetected power value of the information processing device is more thanan upper limit power value set on the information processing device, theupper limit power value of the information processing device to a largervalue than the current upper limit power value within the individualpower value range so that a total of upper limit power values of theinformation processing devices does not exceed the whole upper limitpower value.
 6. The control device according to claim 4, wherein thesetting part is configured to set, in a case where the detected powervalue of the information processing device is less than an upper limitpower value set on the information processing device, the upper limitpower value of the information processing device to a smaller value thanthe current upper limit power value within the individual power valuerange so that a total of upper limit power values of the informationprocessing devices does not exceed the whole upper limit power value. 7.The control device according to claim 4, wherein the setting part isconfigured to set, in a case where the detected power value of theinformation processing device is less than an upper limit power valueset on the information processing device and is not within theindividual power value range, the upper limit power value of theinformation processing device to a smaller value than a lower limitvalue of the individual power value range so that a total of upper limitpower values of the information processing devices does not exceed thewhole upper limit power value.
 8. The control device according to claim4, wherein: the detection part is configured to detect power values ofthe respective information processing devices in sequence; and thesetting part is configured to set, every time a power value of theinformation processing device is detected by the detection part, anupper limit power value of the information processing device so that atotal of upper limit power values of the information processing devicesdoes not exceed the whole upper limit power value.
 9. A control devicecomprising a setting part configured to set an upper limit power valueof each of a plurality of information processing devices to a valuewithin an individual power value range including a predetermined rangeof values which can be set on each of the information processing devicesso that a total of upper limit power values of the informationprocessing devices does not exceed a whole upper limit power value, thewhole upper limit power value being an upper limit power value of awhole system including the information processing devices.
 10. Thecontrol device according to claim 9, comprising a detection partconfigured to detect a power value of each of the information processingdevices, wherein the setting part is configured to set, in a case wherea total of detected power values of the information processing devicesis more than the whole upper limit power value, an upper limit powervalue of each of the information processing devices to a value withinthe individual power value range so that a total of upper limit powervalues of the information processing devices does not exceed the wholeupper limit power value.
 11. The control device according to claim 9,wherein the setting part is configured to set upper limit power valuesof the information processing devices to uniform values withinrespective individual power value ranges so that a total of the upperlimit power values of the information processing devices does not exceedthe whole upper limit power value.
 12. The control device according toclaim 9, comprising a detection part configured to detect a power valueof each of the information processing devices, wherein the setting partis configured to set, in accordance with a result of comparison of thedetected power value of the information processing device with an upperlimit power value set on the information processing device, the upperlimit power value of the information processing device to a value withinthe individual power value range so that a total of upper limit powervalues of the respective information processing devices does not exceedthe whole upper limit power value.
 13. A control method comprisingsetting an upper limit power value of each of a plurality of informationprocessing devices to a value within an individual power value rangeincluding a predetermined range of values which can be set on each ofthe information processing devices so that a total of upper limit powervalues of the information processing devices does not exceed a wholeupper limit power value, the whole upper limit power value being anupper limit power value of a whole system including the informationprocessing devices.
 14. The control method according to claim 13,comprising: detecting a power value of each of the informationprocessing devices; and setting, in a case where a total of detectedpower values of the information processing devices is more than thewhole upper limit power value, an upper limit power value of each of theinformation processing devices to a value within the individual powervalue range so that a total of upper limit power values of theinformation processing devices does not exceed the whole upper limitpower value.
 15. The control method according to claim 13, comprisingsetting upper limit power values of the information processing devicesto uniform values within respective individual power value ranges sothat a total of the upper limit power values of the informationprocessing devices does not exceed the whole upper limit power value.16. The control method according to claim 13, comprising: detecting apower value of each of the information processing devices; and setting,in accordance with a result of comparison of the detected power value ofthe information processing device with an upper limit power value set onthe information processing device, the upper limit power value of theinformation processing device to a value within the individual powervalue range so that a total of upper limit power values of therespective information processing devices does not exceed the wholeupper limit power value.
 17. The control method according to claim 16,comprising setting, in a case where the detected power value of theinformation processing device is more than an upper limit power valueset on the information processing device, the upper limit power value ofthe information processing device to a larger value than the currentupper limit power value within the individual power value range so thata total of upper limit power values of the information processingdevices does not exceed the whole upper limit power value.
 18. Thecontrol method according to claim 16, comprising setting, in a casewhere the detected power value of the information processing device isless than an upper limit power value set on the information processingdevice, the upper limit power value of the information processing deviceto a smaller value than the current upper limit power value within theindividual power value range so that a total of upper limit power valuesof the information processing devices does not exceed the whole upperlimit power value.
 19. The control method according to claim 16,comprising setting, in a case where the detected power value of theinformation processing device is less than an upper limit power valueset on the information processing device and is not within theindividual power value range, the upper limit power value of theinformation processing device to a smaller value than a lower limitvalue of the individual power value range so that a total of upper limitpower values of the information processing devices does not exceed thewhole upper limit power value.
 20. The control method according to claim16, comprising: detecting power values of the respective informationprocessing devices in sequence; and setting, every time a power value ofthe information processing device is detected, an upper limit powervalue of the information processing device so that a total of upperlimit power values of the information processing devices does not exceedthe whole upper limit power value.